Data storage system having a host computer coupled to bank of disk drives through interface comprising plurality of directors, busses, and reference voltage generators

ABSTRACT

A data storage system wherein a host computer is coupled to a bank of disk drives through a system interface. The interface has a memory with a high address memory section and a low address memory section. A plurality of directors control data transfer between the host computer and the bank of disk drives as such data passes through the memory. A pair of high address busses electrically is connected to the high address memory and a pair of low address busses is electrically connected to the low address memory. Each one of the directors is electrically connected to one of the pair of high address busses and one of the pair of low address busses. A front-end portion of the directors is electrically connected to the host computer and a rear-end portion of the directors is electrically connected to the bank of disk drives. The bank of disk drives has a plurality of sets of electrically connected disk drives, each one of the sets being connected to a corresponding one of the input/output interfaces of a corresponding one of the rear-end directors through the adapter card connected to such corresponding one of the rear-end directors and, through the printed circuit board, to the adapter card in the another one of the electrical connectors and to the input/output interface of the rear-end director in such other one of the electrical connectors. Each pair of a plurality of bus arbiters is electrically connected to ends of a corresponding one of the busses. One of the arbiters is a master arbiter and the other a slave arbiter. A pair of reference voltage generator is also connected to ends of each bus.

BACKGROUND OF THE INVENTION

This invention relates generally to data storage systems, and more particularly to data storage systems having redundancy arrangements to protect against total system failure in the event of a failure in a component or subassembly of the storage system.

As is known in the art, large mainframe computer systems require large capacity data storage systems. These large main frame computer systems generally includes data processors which perform many operations on data introduced to the computer system through peripherals including the data storage system. The results of these operations are output to peripherals, including the storage system.

One type of data storage system is a magnetic disk storage system. Here a bank of disk drives and the main frame computer system are coupled together through an interface. The interface includes CPU, or “front end”, controllers (or directors) and “back end” disk controllers (or directors). The interface operates the controllers (or directors) in such a way that they are transparent to the computer. That is, data is stored in, and retrieved from, the bank of disk drives in such a way that the mainframe computer system merely thinks it is operating with one mainframe memory. One such system is described in U.S. Pat. No. 5,206,939, entitled “System and Method for Disk Mapping and Data Retrieval”, inventors Moshe Yanai, Natan Vishlitzky, Bruno Alterescu and Daniel Castel, issued Apr. 27, 1993, and assigned to the same assignee as the present invention.

As described in such U.S. patent, the interface may also include, in addition to the CPU controllers (or directors) and disk controllers (or directors), addressable cache memories. The cache memory is a semiconductor memory and is provided to rapidly store data from the main frame computer system before storage in the disk drives, and, on the other hand, store data from the disk drives prior to being sent to the main frame computer. The cache memory being a semiconductor memory, as distinguished from a magnetic memory as in the case of the disk drives, is much faster than the disk drives in reading and writing data.

The CPU controllers, disk controllers and cache memory are interconnected through a backplane printed circuit board. More particularly, disk controllers are mounted on disk controller printed circuit boards. CPU controllers are mounted on CPU controller printed circuit boards. And, cache memories are mounted on cache memory printed circuit boards. The disk controller, CPU controller and cache memory printed circuit boards plug into the backplane printed circuit board. In order to provide data integrity in case of a failure in a controller, the backplane printed circuit board has a pair of buses. One set the disk controllers is connected to one bus and another set of the disk controllers is connected to the other bus. Likewise, one set the CPU controllers is connected to one bus and another set of the CPU controllers is connected to the other bus. The cache memories are connected to both buses. Each one of the buses provides data, address and control information.

Thus, the use of two buses provides a degree of redundancy to protect against a total system failure in the event that the controllers, or disk drives connected to one bus fail. Further, the use of two buses increases the data transfer bandwidth of the system compared to a system having a single bus.

SUMMARY OF THE INVENTION

In accordance with the invention, a plurality of reference voltage generators is provided, each being electrically connected to a corresponding one of the buses. The bus couples the generated reference voltage to each one of the directors electrically connected to such bus. Each one of the directors electrically connected to the bus includes a reference voltage receiver response to the generated reference voltage for distributing the generated reference voltage among electrical components in such director.

In accordance with another feature of the invention, a pair of reference voltage generators is electrically connecting to ends of a corresponding one of the busses.

In accordance with another feature of the invention, the reference voltage generator includes a input section adapted to vary the reference voltage produced by the reference voltage generator.

In accordance with another feature of the invention, the input section comprises a digital to analog converter.

BRIEF DESCRIPTION OF THE DRAWING

These and other features of the invention will become more readily apparent from the following detailed description when read together with the accompanying drawings, in which;

FIG. 1 shows the relationship between FIGS. 1A and 1B, which together is a block diagram of a data storage system according to the invention;

FIG. 2 shows the relationship between FIGS. 2A and 2B, which together is a diagram showing a layout of the data storage system of FIG. 1;

FIG. 3 is an isometric sketch of a system interface used in the system of FIG. 1;

FIGS. 4A-4C are front, top, and side diagrammatical sketches, respectively, of a backplane printed circuit board and electrical connectors therein used in the system interface of FIG. 3;

FIG. 5 is a schematic diagram of an exemplary one of a plurality of rear-end rectors used in the system of FIG. 1;

FIG. 5A is a schematic diagram of a reference voltage generator used in the director of FIG. 5;

FIG. 6 is a schematic diagram of an exemplary one of a plurality of front-end directors used in the system of FIG. 1;

FIG. 7 is a schematic diagram of a memory section used in the system of FIG. 1;

FIG. 8 is a schematic diagram of a pair of adjacent I/O adapter cards, their associated rear-end directors and SCSI I/O interfaces of the directors interconnected through the backplane printed circuit board of FIG. 3 in accordance with the invention;

FIG. 9 shows the relationship between FIGS. 9A and 9B, which together is a diagram showing a layout of the data storage system of FIG. 1 and the backplane interconnections made between the SCSI I/O interfaces of adjacent ones of the directors;

FIG. 10 is a schematic diagram showing Vref generators used in the system of FIG. 1 and interconnected in accordance with the invention;

FIG. 11 is a schematic diagram of the Vref generator of FIG. 1, such generator being on one of the I/O adapter cards used in the system of FIG. 1;

FIG. 11A is a schematic diagram of an alternative Vref generator of FIG. 1; such generator being on one of the I/O adapter cards used in the system of FIG. 1;

FIG. 12 shows the relationship between FIGS. 12A and 12B, which together is a diagram showing a layout of the data storage system of FIG. 1 and the Vref generaotrs of FIG. 11;

FIG. 13 is a schematic diagram showing connections between directors of the system of FIG. 1 and bus arbiters in such system according to the invention;

FIG. 14 is a schematic diagram of a master and slave arbiter connected to one of a plurality of busses used in the system of FIG. 1 and connected to a plurality of directors used in such system, such arbiters being adapted to arbitrate between requests for access to the bus by such directors;

FIG. 15 is a diagrammatical sketch of a portion of the backplane of FIG. 3, such sketch showing pin connections to configure one of the arbiters in FIG. 14 as the master arbiter and the other one of the arbiters as the slave arbiter;

FIG. 16 is a block diagram of an exemplary of one of the arbiters of FIG. 14 according to the invention;

FIG. 17 a schematic diagram of a priority request synchronizer and decoder used in the arbiter of FIG. 16;

FIG. 18 is a schematic diagram of a section of the arbiter of FIG. 16 used to generate, for each one of a plurality of priority request types issued by the directors, a director grant;

FIG. 19 is a schematic diagram of a low priority and high priority toggle section of the arbiter of FIG. 17 to insure that a low priory request is granted at least after a predetermined grants of a high priority requests and to toggle between a pair of such high priority requests;

FIG. 20 is a schematic diagram of a logic section used in a toggle section of FIG. 19.

DESCRIPTION OF THE PREFERRED EMBODIMENTS System Architecture

Referring now to FIG. 1, a data storage system 10 is shown wherein a host computer 12 is coupled to a bank 14 of disk drives through a system interface 16. The system interface 16 includes a cache memory 18, having high address memory sections 18H and low address memory sections 18L. A plurality of directors 20 ₀-20 ₁₅ is provided for controlling data transfer between the host computer 12 and the bank 14 of disk drives as such data passes through the cache memory 18. A pair of high address busses TH, BH is electrically connected to the high address memory sections 18H. A pair of low address busses TL, BL electrically connected to the low address memory sections 18L. The cache memory 18 has a plurality of storage location addresses. Here, the storage locations having the higher addresses are in the high address memory sections 18H and the storage locations having the lower addresses are in the low address memory sections 18L. It should be noted that each one of the directors 20 ₀-20 ₁₅ is electrically connected to one of the pair of high address busses TH, BH and one of the pair of low address busses TL, BL. Thus, each one of the directors 20 ₀-20 ₁₅ is able to address all locations in the entire cache memory 18 (i.e., to both the high address memory sections 18H and the low address memory sections 18L) and is therefore able to store data in and retrieve data from any storage location in the entire cache memory 18.

More particularly, a rear-end portion of the directors, here directors 20 ₀-20 ₃ and 20 ₁₂-20 ₁₅, is electrically connected to the bank 14 of disk drives through I/O adapter cards 22 ₀-22 ₃ and 22 ₁₂-22 ₁₅ and a front-end portion of the directors, here directors 20 ₄-20 ₁₁, is electrically connected to the host computer 12 through I/O adapter cards 22 ₄-22 ₁₁. It should also be noted that each end of the busses TH, TL, BH, BL terminates in a pair of master and slave arbiters bus arbiters 24 _(AM) _(—) _(TH), 24 _(AS) _(—) _(TH); 24 _(AM) _(—) _(TL), 24 _(AS) _(—) _(TL), 24 _(AM) _(—) _(BH), 24 _(AS) _(—) _(BH); 24 _(AM) _(—) _(BL), 24 _(AS) _(—) _(BL), respectively; and a pair of a pair of reference voltage (Vref) generator 28TH1, 28TH2; 28TL1, 28TL2; 28BH1, 28BH2; 28BL1, 28BL2, respectively.

In operation, when the host computer 12 wishes to store data, the host computer 12 issues a write request to one of the front-end directors 20 ₄-20 ₁₁ to perform a write command. One of the front-end directors 20 ₄-20 ₁₁ replies to the request and asks the host computer 12 for the data. After the request has passed to the requesting one of the front-end directors 20 ₄-20 ₁₁, the director determines the size of the data and reserves space in the cache memory 18 to store the request. The front-end director then produces control signals on either a high address memory bus (TH or BH) or a low address memory bus (TL, BL) connected to such front-end director depending on the location in the cache memory 18 allocated to store the data and enable the transfer to the cache memory 18. The host computer 12 then transfers the data to the front-end director. The front-end director then advises the host computer 12 that the transfer is complete. The front-end director looks up in a Table, not shown, stored in the cache memory 18 to determine which one of the rear-end directors 20 ₁-20 ₃ and 20 ₁₂-20 ₁₅ is to handle this request. The Table maps the host computer 12 address into an address in the bank 14 of disk drives. The front-end director then puts a notification in a “mail box” (not shown and stored in the cache memory 18) for the rear-end director which is to handle the request, the amount of the data and the disk address for the data. Other rear-end directors poll the cache memory 18 when they are idle to check their “mail boxes”. If the polled “mail box” indicates a transfer is to be made, the rear-end director processes the request, addresses the disk drive in the bank, reads the data from the cache memory and writes it into the addresses of a disk drive in the bank 14. When data is to be read from the disk drive to the host computer 12 the system operates in a reciprocal manner.

More particularly, and referring also to FIGS. 2 and 3, the system interface 16 includes a backplane printed circuit board 30 having a plurality of, here 20, electrical connectors 32 ₀-32 ₁₉, or slots, arranged successively and uniformly spaced in a linear array. The electrical connectors 32 ₀-32 ₁₉ are connected selectively to the busses TH, TL, BH, BL, such selective electrical connections being indicated by the “dot” (•) in FIG. 2. Each one of the electrical connectors 32 ₄-32 ₁₅ is adapted to receive a corresponding one of the directors 20 ₄-20 ₁₅, respectively, electrical connectors 32 ₂ and 32 ₃ are adapted to receive high address memory 18H and low address memory 18L of memory section 18 ₁, and electrical connectors 32 ₁₆ and 32 ₁₇ are adapted to receive high address memory 18H and low address memory 18L of memory section 18 ₂, as indicated. It is first noted that electrical connectors 32 ₀, 32 ₁, 32 ₁₈ and 32 ₁₉ are adapted to receive either a director or a memory. Here the electrical connectors 32 ₀, 32 ₁, 32 ₁₈ and 32 ₁₉ are described as having received directors 20 ₀, 20 ₁, 20 ₁₄, and 20 ₁₅, respectively.

It is noted that alternating ones of the directors, (i.e, directors 20 ₀, 20 ₂, 20 ₄, 20 ₆, 20 ₈, 20 ₁₀, 20 ₁₂, and 20 ₁₄), are electrically connected to one of the high address memory busses, here bus TH and to one of the low address memory busses, here bus BL, while the directors interleaved with such alternating ones of the directors (i.e., directors 20 ₁, 20 ₃, 20 ₅, 20 ₇, 20 ₉, 20 ₁₁, 20 ₁₃, and 20 ₁₅), are electrically connected to the other one of the high address memory busses, here bus BH and to the other one of the low address memory busses, here bus TL. It is noted that each one of the busses TH, TL, BH, BL extends along the length of the backplane printed circuit board 30.

Each one of the electrical connectors 32 ₀-32 ₁₉ is identical in construction. An exemplary one thereof, here connector 30 ₀ is shown in FIGS. 4A-4C mounted to the backplane printed circuit board 30. (It is noted that because directors 20 ₀-20 ₁₅ are received in one side of the backplane 30 and input/output I/O adapter cards 22 ₀-22 ₁₅ are received on the other side of the backplane 30, the “backplane” may be regarded as a “midplane” printed circuit board. That is, the “backplane” has printed circuit boards (i.e, an I/O adapter cards 22 ₀-22 ₁₅ and director cards 20 ₀-20 ₁₅ (or memory card 18H, 18L) plugged into opposite sides of it, as shown in FIG. 3).

Here, the exemplary electrical connector 32 ₀ (FIGS. 4A-4C) is a model VHDM manufactured by Teradyne, Boston, Mass., and has a plurality of electrically conductive pins 36 therein which pass through the backplane 30 for electrical connection to the I/O adapter cards 22 ₀-22 ₁₅ and a director cards 20 ₀-20 ₁₅ (or memory card 18) plugged into opposite ends of the pins 36. It is also noted that the electrical connector 32 ₀ is separated into four sections 38 ₁-38 ₄, (i.e., a top left section 38 ₁, a bottom left section 38 ₂, a bottom right section 38 ₃ and a top right section 38 ₄, as indicated.) It is next noted that the upper portion of both top sections 38 ₁ and 38 ₃ provide an upper input/output pin section 40 _(U) for the received directors 20 ₀-20 ₁₅ and I/O adapter cards 22 ₀-22 ₁₅ and the lower portion of both bottom sections 38 ₂ and 38 ₄ provide a lower input/output pin section 40 _(L) for the received directors 20 and I/O adapter cards 22. It is next noted that the lower portion of both top sections 38 ₁ and 38 ₃ provide two quadrants Q₁, Q₃ of pins for the received directors 20 (or memory 18) and that the upper portion of both bottom sections 38 ₂ and 38 ₄ provide two quadrants Q₂, Q₄ of pins for the received directors 20 (or memory 18). Next, it should be noted that an arbiter pin section 42 _(T) is provided between input/output section 40 _(U) and quadrant Q₁ and an arbiter pin section 42 _(B) is provided between input/output section 40 _(L) and quadrant Q₂ for receiving the arbiters 24 _(AM) _(—) _(TH), 24 _(AM) _(—) _(BL), respectively, (FIGS. 1 and 2).

The backplane printed circuit board 30 is a multi-layer printed circuit board having a ground plane conductor 50, as shown in FIG. 4C. It is noted that the four busses TH, TL, BH, BL, are disposed on different electrically isolated layers of the backplane. It is further noted that the busses TH, and TL are disposed on the top (T) portion of the backplane 30; bus TH being electrically connected to the high (H) address memories 18H and bus TL being electrically connected to the low (L) address memories 18L. The busses BH, and BL are disposed on the bottom (B) portion of the backplane 30; bus BH being electrically connected to the high (H) address memories 18H and bus BL being electrically connected to the low (L) address memories 18L. It is noted that, referring to FIG. 2, for the electrical connectors 32 ₄, 32 ₆, 32 ₈, 32 ₁₀, 32 ₁₂, and 32 ₁₄, (i.e., here electrical connector which receive only directors) the pins in quadrant Q₁ are connected to bus TH and the pins in quadrant Q₂ are connected to bus BL. For the electrical connectors 32 ₅, 32 ₇, 32 ₉, 32 ₁₁, 32 ₁₃, and 32 ₁₅, (i.e. electrical connectors which receive only directors) the pins in quadrant Q₁ are connected to bus TL and the pins in quadrant Q₂ are connected to bus BH. For the electrical connectors 32 ₂ and 32 ₃, 32 ₁₆, and 32 ₁₇ (i.e. electrical connectors which receive only memories 18 _(H) or 18 _(L)) the pins in quadrant Q₁ are connected to busses TX or TL, as indicated and the pins in quadrant Q₄ are connected to busses BH or BL, as indicated. Thus, directors 20 are connected to pins in quadrants Q₁ and Q₂ while memories 18 are connected to quadrants Q₁ and Q₄. It is noted that electrical connectors 32 ₀, 32 ₁, 32 ₁₈ and 32 ₁₉ are wired to the quadrants Q₁, Q₂ and Q₄ to provide universal slots adapted to receive either a memory 18 or a director 20,. Thus, here in FIG. 2, electrical connectors 32 ₀ and 32 ₁₈ are connected to busses TH, BL and BH to receive either a director or a high address memory. Electrical connectors 32 ₁ and 32 ₁₉ are connected to busses TL, BH and BL to receive either a director or a low address memory.

Each one of the rear-end portion of the directors 20 ₀-20 ₃ is identical in construction, an exemplary one therefor, here rear-end director 20 ₀ being shown in FIG. 5 to include a pair of central processing sections, CPU X and CPU Y, a dual port random access memory (RAM), and shared resources (Flash memories, etc,) arranged as shown, coupled to the bank 14 of disk drives (FIG. 1) through I/O adapter card 22 ₀ (FIG. 1) via an I/O upper backplane section interface 52 (FIG. 5) and I/O lower backplane section interface 54, as indicated and to a high address memory bus, here TH, and low address memory bus, here BL, via a Q₁ and Q₂ backplane interface sections 56, 58 respectively. The rear-end director 20 ₀ includes a pair of Vref receivers 60, 62 for receiving a Vref voltage generated on the memory busses TH and BL, in a manner to be described in detail in connection with FIGS. 10, 11, and 12. Suffice it to say here, however, that the Vref generated on the memory busses is transmitted on such memory busses to the receivers 60, 62 and that the receivers 60, 62 distribute such received reference voltage Vref locally to the interface sections 56 and 58. An exemplary one of the receivers 60, 62, here receiver 62, is shown in FIG. 5A to include a high input impedance operational amplifier 64 having the non-inverting input thereof fed by the Vref voltage on the memory buss. The output of the amplifier 64 is coupled to the inverting input thereof and provides the local reference voltage Vref for the interfaces 56 and 58. It is noted that the Vref generated on the high address memory bus, i.e., here, TH, is fed to Vref receiver 60 and that receiver 60 provides the reference voltage to the Q₁ backplane section interface section 56. The Vref generated on the low address memory bus, i.e., here, BL, is fed to Vref receiver 62 and that receiver 62 provides the reference voltage to the Q₂ backplane section interface section 58. Finally, it should be noted that the director has a primary output port, P, and a secondary output port, S. As will be described in detail in connection with FIG. 8, the primary port P is connected to both I/O backplane interface 52 and I/O backplane interface 54. Likewise, the secondary port S is connected to both I/O backplane interface 52 and I/O backplane interface 54.

Each one of the front-end portion of the directors 20 ₄-20 ₁₁ is identical in construction. An exemplary one thereof, here director 20 ₄ is shown in detail in FIG. 6 to include a pair of central processing sections, CPU X and CPU Y, a dual port random access memory (RAM), and shared resources (Flash memories, etc,) arranged as shown, coupled to the host computer (through an adapter, not shown), as indicated and to a high address memory bus, here TH, and low address memory bus, here BL, via a Q₁ and Q₂ backplane interface sections 56, 58, respectively. The front-end directors include a pair of the Vref receivers 60 for receiving generated Vref voltage transmitted to the receivers on the high and low address memory busses as described above in connection with FIG. 5. It is noted that here the interfaces 52, 54 are connected to the host computer as described above in connection with FIGS. 1 and 2.

An exemplary one of the memories is shown in FIG. 7 to include a plurality of here four DRAM sections coupled to the top and bottom busses though bus interfaces and ASIC control logics, as indicated.

Dual Initiator

As noted above in connection with FIGS. 1 and 2, a front-end portion of the directors 20 ₄-20 ₁₁ is coupled to the host computer 12 and rear-end portion of the directors 20 ₀-20 ₃ and 20 ₁₂-20 ₁₅ is coupled to the disk drive bank 14. As described in connection with FIG. 5, each one of the rear-end directors 20 ₀-20 ₃ and 20 ₁₂-20 ₁₅ has upper and lower input/output interface 52, 54 coupled to bank 14 of disk drives. The bank 14 of disk drives has a plurality of sets 80 ₀-80 ₃ and 80 ₁₂-80 ₁₅ (FIG. 1) of electrically connected disk drives. Each one of the rear-end directors 20 ₀-20 ₃ and 20 ₁₂-20 ₁₅ has a pair of input/output terminals; i.e. a primary input/output terminals P and a secondary input/output terminals S. Each one of the sets 80 ₀-80 ₃ and 80 ₁₂-80 ₁₅ of disk drives is connected to the primary input/output terminals P and to the secondary input/output terminals S of an adjacent pair of the rear-end directors through an adapter card 22, as indicated in FIG. 1, and in FIGS. 6 and 7, for an exemplary pair of directors, here the pair of adjacent rear-end directors 20 ₀ and 20 ₁. Thus, for redundancy, two different rear-end directors are able to communicate with any one set of disk drives, as shown in FIG. 8. Thus, for example, set 80 ₀ is coupled to the primary terminal P of rear-end director 20 ₀ and, for redundancy in case there is a failure in director 20 ₀, set 80 ₀ is connected to the secondary terminal S of director 20 ₁. Further, directors 20 ₀ and 20 ₁ are on different sets of busses (i.e., busses TH and BL for director 20 ₀ and busses TL and BH for director 20 ₁) for additional redundancy.

More particularly, the primary input/output terminals P of director 20 ₀ are connected to: (1) the disk drive set 80 ₀ through the backplane 30 and to the I/O adapter card 22 ₀; and (2) the secondary input/output S of the adjacent director 20 ₁ through the backplane 30, as shown in FIG. 5. Reciprocally, the primary input/output terminals P of director 20 ₁ are connected to: (1) the disk drive set 80 ₁ through the backplane 30 and the I/O adapter card 22 ₁; and (2) the secondary input/output pins S of the adjacent director 20 ₀ through the backplane 30.

With a SCSI interface, as shown in FIGS. 8 and 9, each one of the input/output interfaces 52, 54 includes a primary SCSI initiator section and a secondary, or redundant (i.e. “back-up”) SCSI initiator section. The primary SCSI initiator section includes four identical SCSI initiator chips: LDP, LCP, UDP, and UCP, as indicated, each adapted to initiate, or start, a transfer to a target, or destination, according to SCSI protocol. The secondary SCSI initiator section also includes four identical SCSI initiator chips: LDS, LCS, UDS, and UCS, as indicated, each adapted to initiate, or start, a transfer to a target, or destination, according to the SCSI protocol.

Here, a SCSI transfer uses a of SCSI initiator. Thus, the CPU Y of a director is coupled to the primary LDP and LCP chips of the director and the primary UDP and UCP chips of the director are coupled to the X CPU section of such director. For redundancy, the CPU X of a director is coupled to the secondary UDS and UCS chips of the director, and the secondary LDS and LCS chips of the director are coupled to the Y CPU section of such director. As noted in connection with FIG. 5, the X and Y CPU sections are coupled to busses TH and BL or to the busses BH and TL depending on the slot used by the director.

Thus, referring to FIG. 9, for an exemplary pair of adjacent electrical connectors 32 ₀, 32 ₁, as noted above, the UCP pins of electrical connector 32 ₀ are connected the UCS pins of electrical connector 32 ₁ through printed wires in the layers of the backplane printed circuit board 30. The UCS pins of electrical connector 32, are connected the UCP pins of electrical connector 32, through printed wires in the layers of the backplane printed circuit board 30. The LCP pins of electrical connector 32 ₀ are connected the LCS pins of electrical connector 32 ₁ through printed wires in the layers of the backplane printed circuit board 30. The LCS pins of electrical connector 32 ₀ are connected the LCP pins of electrical connector 32 ₁ through printed wires in the layers of the backplane printed circuit board 30. As noted particularly from FIG. 9, this arrangement is used for the rear-end directors connected to the bank 14 of disk drives and to the universal connectors 32 ₀, 32 ₁, 32 ₁₄ and 32 ₁₅ which, as noted above, are adapted to receive directors 20 ₁, 20 ₂, 20 ₁₄ and 20 ₁₅, respectively. It is noted that these pins LDP, LCP, UDP, UCP, LDS, LCS, UDS, UCS, are interconnected between adjacent directors other that for those in the universal connectors for enabling a degree of freedom in configuration, i.e., the electrical connectors for directors 20 ₄, 20 ₅, enables such directors to be connected to the bank of disk drives instead of to the host computer.

Vref Generator/Receiver

The system 10 (FIG. 1) has a plurality of reference voltage (Vref) generators 28TH1, 28TH2; 28TL1, 28TL2; 28BH1, 28BH2; 28BL1, 28BL2, arranged as shown in FIGS. 10 and 12. These reference voltage generators are used to supply a reference voltage, Vref=1.0 volts, for Gunning Transistor Logic Plus (GTLP) used in interfaces 56 and 58 (FIG. 5) used in the directors and GTLP circuitry in the memories 18H, 18L. Each bus couples the generated reference voltage to each one of the directors electrically connected to such bus, as shown in FIG. 10. Each one of the directors electrically connected to the bus includes, as described above in connection with FIGS. 5, 5A and 6, a reference voltage receiver response to the generated reference voltage for distributing the generated reference voltage among electrical components in such director. Thus, as noted above, the rear-end directors include a Vref receiver 60 for receiving generated Vref voltage transmitted to the receivers 60 on the high and low address memory busses, e.g., TH and BL, and for distributing such received voltages to the interface sections 56 and 58. As noted above, an exemplary one of the receivers 60 is shown in FIG. 5A to include a high input impedance operation amplifier 64 having the non-inverting input thereof fed by the Vref voltages on the memory busses. The output of the amplifier 64 is coupled to the inverting input thereof and provides the local reference voltage Vref for the interfaces 56 and 58.

It is noted that Vref receiver 60 is also in the front-end directors and the high address memories 18H and the low address memories 18L. Thus, rather that merely transmit Vref voltages on the busses and having resistor dividers in the directors and memories, receiver 60 is used with high input impedance operational amplifier 64 (FIG. 5A) to minimize the amount of current on the bus, and therefore the associated voltage drop along the bus, and to reduce the effect of change in the value of the resistors in the resistor divider network and its associated adverse effect on the accuracy of the Vref used by the GTLP circuits in the directors and memories.

Referring also to FIGS. 11 and 12, it is noted that the generators 28TH1, 28TH2; 28TL1, 28TL2; 28BH1, 28BH2; 28BL1, 28BL2 are connected to the terminating ends of the a bus and are disposed on the adapter cards 20 ₀, 20 ₁, 20 ₁₄ and 20 ₁₅ in the electrical connectors 32 ₀, 32 ₁, 32 ₁₈ and 32 ₁₉, respectively. It is also noted that both directors and memories include a Vref receiver 60. Each one of the reference voltage generators is identical in construction. An exemplary pair of the reference voltage generators (28TH1 and 28BL1) is shown in FIG. 11. A Vtt generator includes a pair of reference supply voltage sources 60, 62, here a +2.5 voltage supply, and four linear voltage regulators 64, 66, 68 and 69, one pair of the four linear voltage regulators 64, 68 being supplied by one of the two reference voltage sources 60 and the other pair of the four linear voltage regulators 66, 69 being supplied by the other one of the two reference voltage sources 62, as shown. The outputs of a pair of the linear regulators 64, 66 are connected together (through resistors, as shown) for redundancy to provide a Vtt generated voltage which is coupled to the Vref generator 28TH1, as shown. The outputs of other pair of the linear regulators 68, 69 are connected together (through resistors, as shown) for redundancy to provide a Vtt generated voltage which is coupled to the Vref generator 28TH2, as shown. An exemplary pair of the Vref generators 28TH1. 28BL1 are shown to include a pair of digital to analog converters (DACs) coupled via switches 70 to inputs of a high input impedance operational amplifier 72, as shown. The output of the amplifiers 72 is coupled to the input thereof in a negative feedback relationship and produces the generated Vref for the top high address memory bus, TH, as shown in FIG. 11.

The DACs enable one to vary the level of the reference voltage to, for example, determine the margin allowable by the system and/or to choose an optimum Vref level for the system. This is enabled by placing a digital word to the DAC and coupling the corresponding analog voltage level through an activated switch to the non-inverting input of the operational amplifier.

It is noted that diodes 81 are isolation diodes. Thus, the one of the Vref generators 28TH1, 28TH2 which produces the higher voltage supplies the bus with such voltage. It both Vref generators 28TH1, 28TH2 produce the same voltage, they current share. Further, the diodes 81 provide isolation if one of the Vref generators 28TH1, 28TH2 fails.

Alternatively, the reference voltage generators may include 2.5 volt fixed reference voltage sources arranged as shown in FIG. 11A to provide the Vtt generator.

Arbiter

Referring again to FIG. 1, as noted above, a plurality of pairs of master and slave bus arbiters 24 _(AM) _(—) _(TH), 24 _(AS) _(—) _(TH); 24 _(AM) _(—) _(TL), 24 _(AS) _(—) _(TL), 24 _(AM) _(—) _(BH), 24 _(AS) _(—) _(BH); 24 _(AM) _(—) _(BL), 24 _(AS) _(—) _(BL) is provided. Referring also to FIG. 13, requests for one of the busses TH, TL, BH, BL are made by the eight directors connected to such one of the busses. Thus, for exemplary bus BL, requests for bus BL may be made by the eight directors 20 ₀, 20 ₂, 20 ₄, 20 ₆, 20 ₈, 20 ₁₀, 20 ₁₂ and 20 ₁₄ connected to such bus BL. A pair of arbiters 24 _(AS) _(—) _(BL) and 24 _(AM) _(—) _(BL) is connected to the ends of bus BL. One of each of the pairs of bus arbiters is a master arbiter, here arbiter 24 _(AM) _(—) _(BL) and the other one of the pair of arbiters is a slave arbiter, here 24 _(AS) _(—) _(BL). The master arbiter 24 _(AM) _(—) _(BL) provides arbitration between directors connected to the bus BL and, if one of the directors connected to such bus BL indicates a fault, the master arbiter 24 _(AM-BL) is disabled and the slave arbiter 24 _(AS) _(—) _(BL) is enable to provide such arbitration. More particularly, the I/O adapter cards 22 ₀, 22 ₁₄ connected to the terminating ends of the bus BL received in end ones of the electrical connectors 32 ₀, 32 ₁₉, respectively, have thereon the slave arbiter 24 _(AS) _(—) _(BL) and master arbiter 24 _(AM) _(—) _(BL), respectively, electrically connected to bus BL. (Referring to FIG. 2, it is noted that I/O adapter card 22 ₀ has slave arbiters 24 _(AS) _(—) _(TH) and 24 _(AS) _(—) _(BL); I/O adapter card 22 ₁ has slave arbiters 24 _(AS) _(—) _(BH) and 24 _(AS) _(—) _(TL); I/O adapter card 22 ₁₄ has master arbiters 24 _(AM) _(—) _(TH) and 24 _(AM) _(—) _(BL); and, I/O adapter card 22 ₁₅ has master arbiters 24 _(AM) _(—) _(BH) and 24 _(AM) _(—) _(TL)). Each one of the arbiters 24 _(AM) _(—) _(BL) or 24 _(AS) _(—) _(BL) is identical in construction and is adapted to respond to the priority codes of the directors coupled thereto and assign access to such bus in accordance with a predetermined criteria, to be described.

Referring to FIG. 15, it is noted that electrical pins P₁ have the same physical location in each one of the electrical connectors 32 ₀, 32 ₁, 32 ₁₈ and 32 ₁₉. Further, it is noted that the pins P₁ in electrical connectors 32 ₀ and 32 ₁ are connected to ground via the ground plane of the backplane printed circuit board while the pins P₁ in the electrical connector 32 ₁₄ and 32 ₁₅ are not connected; i.e., are open circuit, that is, are terminated in a high impedance. Thus, one of the electrical connectors 32 ₀, 32 ₁₈ at one end of the bus BL, here connector 32 ₁₈ has a reference electrical potential on pin P₁ thereof, here ground, and the one of the electrical connectors 32 ₀ at the other end of the bus has a high impedance on pin P₁ thereof, here an open circuit (i.e, no connection, NC). The, mating pins P₁ in the I/O adapter card received in electrical connectors 32 ₀, 32 ₁ are therefore connected to the grounded pins, while the mating pins P₁ in the I/O adapter card received in electrical connectors 32 ₁₈, 32 ₁₉ are therefore connected to an open circuit. Plugging an adapter card in electrical connectors 32 ₀ and 32 ₁ configures the arbiter thereon into a slave arbiter while plugging the same adapter card into electrical connector 32 ₁₈, 22 ₁₉ configures the same arbiter as a slave arbiter.

More particularly, referring also to FIG. 14, it is noted that, and considering the exemplary master and slave arbiters connected to the ends of bus BL, the master arbiter 24 _(AM) _(—) _(BL) has identical circuitry as the slave arbiter 24 _(AS) _(—) _(BL). Thus, each includes identical master/slave arbiter enable circuits 90 and identical master and slave arbiter control circuitry 25 _(AM) _(—) _(BL), 25 _(AS) _(—) _(BL), respectively. The master/slave arbiter enable circuits 90 each include an exclusive OR gate 92 having a pair of inputs 94, 96. One of the pair of inputs, here input 94, is connected to a supply voltage, Vcc, through a resistor R₁ and to the directors connected to the bus BL via a one bit line MS_ARB, while the other input 96 is connected to pin P₁ and to Vcc through resistor R₂ to the directors connected to the bus BL. As noted above, when pin P₁ is connected to ground, as when the adapter card is plugged into electrical connector 32 ₀, the arbiter will be configured as a slave arbiter 24 _(AS) _(—) _(BL) while when the same adapter card is plugged into electrical connector 32 ₁₈, the arbiter will be configured as a master arbiter 24 _(AM) _(—) _(BL). The resulting configuration for an exemplary one of the busses, here bus EL, is shown in FIG. 14.

At power-up, a high logic signal is produced on the one bit MS_ARB line (FIG. 14). The high logic level signal on the one bit MS_ARB line is fed to inputs 94 of both master/slave arbiter enable circuits 90. In response to the high logic level, the exclusive OR gate 92 of master arbiter 24 _(AM) _(—) _(BL) produces a low enable signal to thereby enable the master arbiter control 25 _(AM) _(—) _(BL) and exclusive OR gate 92 of slave arbiter 24 _(AS) _(—) _(BL), produces a high enable signal to thereby disable slave arbiter 25 _(AS) _(—) _(BL). If a director issues a two bit priority code and no response is received by the arbiter after a predetermined time, the same director which issued the priority code for the bus produces a low logic signal to inputs 94 of both master/slave arbiter enable circuits 90. More particularly, if a director requests the bus, and a bus grant is not received within a predetermined time, for example, 150 milliseconds, the director detects an arbitration timeout error, assumes that the master arbiter has failed, and produces a low logic level on the one bit MS_ARB line (FIG. 14). In response to the low logic level, the exclusive OR gate 92 in the slave arbiter 24 _(AS) _(—) _(BL) produces a low enable signal to thereby enable the slave arbiter control 25 _(AS) _(—) _(BL) and the exclusive OR gate 92 in the master arbiter 24 _(AM) _(—) _(BL) produces a high enable signal to thereby disable the master arbiter control 25 _(AM) _(—) _(BL).

As noted above, each one of the directors is adapted to produce on the bus BL coupled thereto a plural, here two-bit priority code REQCD. The bus arbiter 24 _(AM) _(—) _(BL), for example, is responsive to the priority codes of the directors coupled thereto and assigns access to such bus in accordance with a predetermined criteria. Here, the two-bit priority code REQCD provides one of three levels of priority: a low priority and two types of high priority; i.e., a DMA high priority and a DSA high priority. (A DMA high priority is used for a read/write multiple data word transfer while a DSA high priority is used for a read/write single data word transfer). The arbiter assigns the lowest priority to the directors issuing the low priority code and toggles alternatively between directors issuing either one of the two high priority requests in a manner to be described. In any event, a low priority request is granted by the arbiter to a director which has been issuing such request for a predetermined number of director requests.

Referring now to FIG. 16, an exemplary one of the arbiter controls 25 _(AM) _(—) _(BL), 25 _(AS) _(—) _(BL), here arbiter control 25 _(AM) _(—) _(BL), is shown in detail. (As noted above, each of the arbiter controls 25 _(AM) _(—) _(BL, 25) _(AS) _(—) _(BL) is identical in construction.) The arbiter control 25 _(AM) _(—) _(BL) is shown to include a request synchronizer and decoder section 100, shown in more detail in FIG. 17, a director granter 102 for each of the three types of priorities, shown in more detail in FIG. 18, and a low priority/high priority toggle selector 104, shown in more detail in FIG. 19.

Referring to FIG. 17, the request synchronizer and decoder section 100 is used to first synchronize the asynchronous two-bit priority requests (REQCDs) from the eight directors 20 ₀, 20 ₂, 20 ₄, 20 ₆, 20 ₈, 20 ₁₀, 20 ₁₂, to a clock, CLK. The request synchronizer and decoder section 100 includes a plurality of here eight synchronization latching sections 106 ₁-106 ₈, each one thereof being fed by the two-bit priority code of a corresponding one of the eight directors 20 ₀, 20 ₂, 20 ₄, 20 ₆, 20 ₈, 20 ₁₀, 20 ₁₂ coupled to the arbiter control 25 _(AM-BL). Here, the two-bit priority codes REQCDs (i.e., one bit being REQCD_(—)0 and the other bit being REQCD_(—)1) are represented by binary logic signals as follows:

TABLE I Priority Request REQCD_0 REQCD_1 Type 0 0 Low Priority 0 1 High Priority_DMA 1 0 High Priority_DSA 1 1 No Request

Each one of eight synchronization latching sections 106 ₁-106 ₈ is identical in construction. An exemplary one thereof, here section 106 ₁, is shown to include an NAND gate 110 fed by the two-bit priority code of the one of the eight directors, here director 20 ₀ fed thereto. Also provided are three flip/flop (F/F) sections 112, 114, 116 arranged as shown having their clock terminals fed by the CLK. Thus, after a clock pulse CLK, the two-bit priority code of the director issuing such code since the last clock CLK are stored in the flip/flop 116. The flip/flop 114 produces a logic signal on line REQ DIR0 to indicate that a valid code has been detected.

The outputs of the here eight synchronization latching sections 106 ₀-106 ₇ are fed to a corresponding one of here eight decoders 120 ₀-120 ₇ to decode the two-bit word fed thereto to one of the three priority levels; i.e., low priority, high priority_DMA; or high priority_DSA in response to the logic signal on line REQ DIR0 indicating that a valid code has been detected. Here, a request is represented by a logic 1 and the absence of a request is represented by a logic 0. Each one of the eight decoders 120 ₀-120 ₇ produces the decoded priority request for a corresponding one of the eight directors 20 ₀-20 ₇, as indicated. Thus, for example, decoder 120 ₀ produces decoded priority requests LP_(—)0, DMA_(—)0, and DSA_(—)0 for director 20 ₀ and decoder 120 ₇ produces decoded priority requests LP_(—)7, DMA_(—)7, and DSA_(—)7 for director 20 ₇. The three priority requests are grouped as indicated for each of the eight directors 20 ₀, 20 ₂, 20 ₄, 20 ₆, 20 ₈, 20 ₁₀, 20 ₁₂, 20 ₁₄ into a low priority set of eight LP_REQS request (i.e., LP_(—)0 through LP_(—)7, respectively, provided by decoders 120 ₀-120 ₇); a set of eight first high priority set of HP_DMA_REQS requests (i.e., DMA_(—)0 through DMA_(—)7, respectively, provided by decoders 120 ₀-120 ₇); and a set of eight second high priority set of HP_DSA_REQS requests (i.e., DSA_(—)0 through DSA_(—)7, respectively, provided by decoders 120 ₀-120 ₇), as shown. Here, as noted above, a request is a logic 1 and the absence of a request is a logic 0. Thus, if the director 20 ₀ issues a DSA request when there is a CLK, line DSA_(—)0 is a logic 1; whereas if the director 20 ₀ does not issues a DSA request when there is a CLK, line DSA_(—)0 is a logic 0. In like manner, if the director 20 ₁₄ issues a DSA request when there is a CLK, line DSA_(—)7 is a logic 1; whereas if the director 20 ₁₄ does not issues a DSA request when there is a CLK, line DSA_(—)7 is a logic 0.

The three sets of priority requests (i.e., a set of eight LP_REQS request, a set of eight HP_DMA_REQS requests; and a set of eight HP_DSA_REQS requests) are fed by the request synchronizer and decoder 100 to the director granter 102 (FIG. 18) for each of the three types of priorities. The director granter 102, for each of the three types of priorities, includes three sections 122 ₁, 122 ₂ and 122 ₃, each of identical construction and fed by a corresponding one of the three sets of requests (i.e., the set of eight low priority requests, LP_REQS requests, the set of eight first type high priority requests, HP_DMA_REQS requests; and the set of eight second type high priority requests, HP_DSA_REQS requests). An exemplary one of the identical sections 122 ₁, 122 ₂ and 122 ₃, here the section 122 ₁ coupled to the set of eight LP-REQS, is shown to include an 8:1 multiplexer 124 fed by each of the eight low priority request lines LP_(—)0 through LP_(—)7, a three bit counter 126 incremented by the clock CLK and enabled by the output of an NAND gate 128. The NAND gate 128 is fed by the output of the multiplexer 124. An inverted input of NAND gate 128 is fed by a low priority feedback signal, LP_FB, which indicates an active request has been granted in a manner to be described in more detail hereinafter thus releasing the polling operation of the multiplexer 124 in searching for the next active low priority request without loss of processing time. Suffice it to say here, however, that the counter 126 is enabled, (i.e., when there is a low priory request from a director and the request is not being processed), the counter 126, which is initially reset to 0, increments in response to each CLK. Thus, each time the contents of the three bit counter 116 increments, a different one of the low priority requests from the eight directors 20 ₀, 20 ₂, 20 ₄, 20 ₆, 20 ₈, 20 ₁₀, 20 ₁₂, 20 ₁₄ polled (i.e., is coupled to the output of the multiplexer 124) to provide an indication of whether the polled director produces a low priority signal on a line in the set LP_REQ. The count of the counter 126, (i.e., a three bit code on bus LP_REQCD, low priority director request code) thus indicates which one of the directors is producing the low priority request. It is noted that the low priority signal on line LP_REQ is produced when one of the eight directors 20 ₀, 20 ₂, 20 ₄, 20 ₆, 20 ₈, 20 ₁₀, 20 ₁₂, 20 ₁₄ is selected by the contents of the counter 126 only if such selected director produces a low priority request. Thus, when enable to increment eight times, the director granter 102, for each of the three types of priorities, has indicated the type of priority request for each of the eight directors 20 ₀, 20 ₂, 20 ₄, 20 ₆, 20 ₈, 20 ₁₀, 20 ₁₂, 20 ₁₄. That is, after eight CLKs all requests from each of the eight directors have been polled.

The low priority/high priority toggle selector 104 is shown in more detail in FIG. 19 to include AND gates 130 through 140, a two-bit counter 142, OR gates 144 through 152, a logic section 154 (shown in detail in FIG. 20), and gates 156 through 160, all arranged as shown. The logic section 154, shown in detail in FIG. 20, is fed by logic signals on lines DMA_FB, DSA_FB, and DSA/{overscore (DMA)} (i.e., Previous Grant), to be described, and is arranged to implement the following priority arbitration Rules with regard to the two types of high priorities, i.e., DMA and DSA:

TABLE II Previous Grant DSA_FB DMA_FB DSA/{overscore (DMA)} Next Grant no DSA no DMA previous grant a DMA request request request DMA request no DSA no DMA previous grant a DSA request request request DSA request no DSA DMA previous grant DMA request request request DMA request no DSA DMA previous grant DMA request request request DSA request DSA no DMA previous grant DSA request request request DMA request DSA no DMA previous grant DSA request request request DSA request DSA DMA previous grant DSA request request request DMA request DSA DMA previous grant DMA request request request DSA request

Thus, the logic network 154 implements the following logic truth Table:

TABLE III INPUTS OUTPUT (AFTER CLK) DSA_FB DMA_FB DSA/{overscore (DMA)} DSA/{overscore (DMA)} 0 0 0 0 0 0 1 1 0 1 0 0 0 1 1 0 1 0 0 1 1 0 1 1 1 1 0 1 1 1 1 0

In operation, if there is a low priority request and there had been three high priority type requests, as counted by two-bit counter 142, AND gate 130 produces a logic 1 on line LP_FB which passes through OR gates 144, 150 to indicate on resume strobe line RES_STRB (FIGS. 14 and 19) to all the directors to indicate that a director has been given access to the bus, BL. It is noted that the output of AND gate 130 is fed to an inverting input of AND gates 132-140 thereby causing AND gates 132-140 to produce a logic 0 when AND gate 130 produces a logic 1. Further, if there is neither a DMA or DSA request, as indicated by a logic 1 and a low priority request, a the output of AND gate 132 produces a logic 1 which passes through OR gates 144, 150 to indicate on resume strobe line RES_STRB (FIGS. 14 and 19) to all directors that a director has been given access to the bus, BL.

If there is a DMA request and no DSA request, AND gate 134 produces a logic 1 on line DMA_FB which passes through OR gates 146, 150 to indicate on the resume strobe line RES_STRB to the directors that a director has been given access to the bus. If there is a DSA request and no DMA request, AND gate 140 produces a logic 1 on line DSA_FB which passes through OR gates 148, 150 to indicate on the resume strobe line RES_STRB to the directors that a director has been given access to the bus. If there is a DMA request and a DSA request either AND gate 134 or AND gate 136 produces a logic 1 depending on the previous DSA or DMA request (i.e., as established by Tables II and III above).

Further, a logic 1 signal on one of the lines LP_FB, DMA_FB or DSA_FB enables gates 156, 158, 160, respectively, which are fed the three-bit signals LP_REQCD, DMA_REQCD and DSA_REQCD, to pass the three-bit director designation code on bus RES_CD. Thus, the signal on bus RES_CD provides an indication of the one of the eight directors coupled to bus BL which is being granted access to the bus BL and bus RES_CD provides such indication to such eight directors 20 ₀, 20 ₂, 20 ₄, 20 ₆, 20 ₈, 20 ₁₀, 20 ₁₂, 20 ₁₄.

It is noted that a director granted access to the bus after the arbitration, maintains the access to the bus as long as its request code REQCD is asserted on the bus. When the request code is removed from the bus by the director, the arbiter control 25 _(AM) _(—) _(BL), for example, produces a logic 0 on the resume strobe bus RES_STRB (which indicates that one of the directors has access to the bus) and the arbitration process is allowed to repeat in the manner described above. Further, as noted above, the NAND gate 128 is fed by the output of the multiplexer 124. An inverted input of NAND gate 128 is fed by a low priority feedback signal, LP_FB, which indicates an active request has been granted thus releasing the polling operation of the multiplexer 124 in searching for the next active low priority request without loss of processing time.

Other embodiments are within the spirit and scope of the appended claims. For example, backplanes may be used with a different larger or smaller number of electrical connectors than shown in FIG. 1. Further, the universal slots may located in other positions than those shown in FIG. 1. 

What is claimed is:
 1. A data storage system wherein a host computer is coupled to a bank of disk drives through an interface, such interface comprising: a memory; a plurality of directors for controlling data transfer between the host computer and the bank of disk drives as such data passes through the memory; a plurality of busses in communication with the directors and the memory; a plurality of reference voltage generators each being electrically connected to a corresponding one of the buses, such bus coupling the generated reference voltage to each one of the directors electrically connected to such bus; and wherein each one of the directors electrically connected to the bus includes a reference voltage receiver response to the generated reference voltage for distributing the generated reference voltage among electrical components in such director.
 2. The system recited in claim 1 wherein one of the pair of reference voltage generators is electrically connecting to ends of a corresponding one of the busses.
 3. The system recited in claim 2 wherein the reference voltage generator includes a input section adapted to vary the reference voltage produced by the reference voltage generator.
 4. The system recited in claim 3 wherein the input second comprises a digital to analog converter.
 5. A data storage system wherein a host computer is coupled to a bank of disk drives through an interface, such interface comprising: a memory comprising a high address memory section and a low address memory section; a plurality of directors for controlling data transfer between the host computer and the bank of disk drives as such data passes through the memory; a pair of high address busses electrically connected to the high address memory and a pair of low address busses electrically connected to the low address memory; and wherein each one of the directors is electrically connected to one of the pair of high address busses and one of the pair of low address busses; a reference voltage generator electrically connected to a corresponding one of the buses, such bus coupling the generated reference voltage to each one of the directors electrically connected to such bus; and wherein each one of the directors electrically connected to the bus includes a reference voltage receiver response to the generated reference voltage for distributing the generated reference voltage among electrical components in such director.
 6. The system recited in claim 5 the reference voltage generator is electrically connected to an end of the bus.
 7. The system recited in claim 6 including a second voltage reference generator connected to another end of the buss. 